KR20120014033A - Method and apparatus for accessing an uplink random access channel in a single carrier frequency division multiple access system - Google Patents

Abstract

In a single carrier frequency division multiple access (SC-FDMA) system, a method and apparatus for accessing a contention based uplink random access channel (RACH) is disclosed. The wireless transmit / receive unit (WTRU) randomly selects a RACH subchannel and a signature from among a plurality of available RACH subchannels and signatures. The WTRU transmits the preamble using the selected signature on the selected RACH subchannel at a predetermined or calculated transmit power level. The base station monitors the RACH to detect the preamble and sends an acquisition indicator (AI) to the WTRU when a signature is detected on the RACH. When receiving an acknowledgment, the WTRU sends a message portion to the base station. If the negative response or no response is received, the WTRU retransmits the preamble.

Description

Method and apparatus for accessing uplink random access channel in single carrier frequency division multiple access system {METHOD AND APPARATUS FOR ACCESSING AN UPLINK RANDOM ACCESS CHANNEL IN A SINGLE CARRIER FREQUENCY DIVISION MULTIPLE ACCESS SYSTEM}

The present invention relates to a wireless communication system. More specifically, the present invention relates to a method and apparatus for accessing a contention based uplink random access channel (RACH) in a single carrier frequency division multiple access (SC-FDMA) system.

Third Generation Partnership Projects (3GPP) and 3GPP2 are currently considering long term evolution (LTE) of universal mobile telecommunication system (UTS) terrestrial radio access (UTRA). Currently, SC-FDMA has been adopted for the uplink air interface of the evolved UTRA.

In an SC-FDMA system, a plurality of orthogonal subcarriers are transmitted simultaneously. These subcarriers are divided into a plurality of subcarrier blocks (known as resource blocks (RBs)). A block of subcarriers is a basic resource unit in an SC-FDMA system. The subcarrier block may be either a concentrated subcarrier block or a distributed subcarrier block. The centralized subcarrier block is a set of consecutive subcarriers, and the distributed subcarrier block is a set of discrete subcarriers spaced at equal intervals.

1 shows two centralized subcarrier blocks each containing four consecutive subcarriers. The centralized subcarrier block is a basic scheduling unit for uplink transmission in the centralized mode SC-FDMA system. 2 shows two distributed subcarrier blocks. In this example, the distributed subcarrier block 1 comprises subcarriers 1, 5 and 9, and the distributed subcarrier block 2 comprises subcarriers 3, 7, 11. The distributed subcarrier block is a basic scheduling unit for uplink transmission in a distributed mode SC-FDMA system. Depending on the data rate or buffer state, Node B allocates at least one subcarrier block for uplink transmission of a wireless transmit / receive unit (WTRU).

When the WTRU transitions from idle mode to connected mode, the WTRU needs to communicate with the base station (or network) using the RACH, which is a contention based channel. The RACH transmission of the WTRU has two parts (preamble part and message part). In a conventional wideband code division multiple access (WCDMA) system (up to release 6), a transmit power ramping scheme is used to access the RACH. The WTRU starts transmitting the preamp to the base station using a very low (or minimal) initial transmit power level. If the preamble is successfully decoded by the base station, the base station sends an acknowledgment (ACK) to the WTRU on the Acquisition Indicator Channel (AICH). If the base station fails to decode the preamble, the base station sends a negative acknowledgment (NACK). If the WTRU receives a NACK or does not receive a response, the WTRU retransmits the preamble while ramping up the transmit power level in a subsequent transmission time interval (TTI).

This power ramp-up process starting with low power or minimum power undesirably introduces additional delay in uplink random access.

The present invention relates to a method and apparatus for accessing contention-based uplink RACH in SC-FDMA system. The WTRU randomly selects a RACH subchannel and a signature from among a plurality of available RACH subchannels and signatures. The WTRU transmits the preamble at a preselected transmit power via the selected RACH subchannel and using the selected signature. The base station monitors the RACH subchannels to detect the preamble. The base station sends an acquisition indicator (AI) to the WTRU when the signature is detected on the RACH. When the WTRU receives an ACK, the WTRU sends a random access message to the base station. If the WTRU receives a NACK or does not receive a response, the WTRU retransmits the preamble. The base station may send power adjustments and / or timing and frequency corrections for the message portion.

In a single carrier frequency division multiple access (SC-FDMA) system, a method and apparatus are provided for accessing a contention-based uplink random access channel (RACH).

1 shows a conventional centralized subcarrier block of SC-FDMA.
2 shows a conventional distributed subcarrier block of SC-FDMA.
3 is a flowchart of a process for accessing contention based RACH in an SC-FDMA system in accordance with the present invention.
4 is a flowchart of a process for processing a preamble at a base station in accordance with the present invention.
5 is a block diagram of a WTRU implementing the process of FIG. 3.
6 is a block diagram of a base station implementing the process of FIG.

In the following, the term "WTRU" includes but is not limited to user equipment (UE), mobile station (STA), fixed subscriber unit or mobile subscriber unit, pager, or any other type of device capable of operating in a wireless environment. It doesn't work. As referred to hereinafter, the term "base station" includes, but is not limited to, Node B, site controller, access point (AP) or any other type of interface device in a wireless environment.

Features of the invention may be integrated on an integrated circuit (IC) or may be configured in a circuit that includes a plurality of interconnecting components.

3 is a flow diagram of a process 300 for accessing a contention based RACH in an SC-FDMA system in accordance with the present invention. After successfully performing cell search, the WTRU obtains RACH control parameters (step 302). RACH control parameters include, but are not limited to, at least one of the following elements.

1) a predetermined transmit power (optional) or uplink interference level at Node B for the preamble, which helps the WTRU determine the transmit power of the preamble;

2) sustain level of transmission on the RACH;

3) preamble scrambling code;

4) optional message length in time, frequency or both;

5) AICH transmission timing parameter;

6) a set of available signatures and a set of available RACH subchannels for each of a plurality of access service classes (ASCs);

7) maximum preamble retransmission limit;

8) power offset P _pm measured in dB between the power of the control portion of the random access message and the power of the remainder of the random access message;

9) a set of transmission format parameters for each transmission format, including a power offset between the data portion and the control portion of the random access message.

10) One-to-one mapping relationship of time and frequency location between RACH and AICH.

The RACH may be defined by at least one subcarrier (or at least one subcarrier block) over at least one time slot. Alternatively, the RACH may be defined by at least one subcarrier (or at least one subcarrier block) over at least one time slot with at least one spreading code. If the RACH is defined with several subcarriers, these subcarriers are contiguous or evenly spaced apart. Similarly, if the RACH is defined with several subcarrier blocks, these subcarrier blocks may be centralized subcarrier blocks or distributed subcarrier blocks. Because of the less ambiguity of timing detection at the receiver (eg, Node B), consecutive subcarriers and concentrated subcarrier blocks are preferred over equally spaced subcarriers and distributed subcarrier blocks.

If it is determined in step 304 that there is data to be transmitted, the WTRU selects an ASC from the set of available ASCs (step 306). Each ASC is associated with an identifier i and a persistence value P _i of the RACH subchannel set.

The preamble retransmission counter is set to zero (step 308). The preamble retransmission counter is then incremented by one before initiating transmission of the preamble (step 310). It is determined whether the preamble retransmission counter exceeds the maximum preamble retransmission limit (step 312). If this retransmission counter exceeds the maximum preamble retransmission limit, it indicates to the upper layer that the maximum preamble retransmission limit has been reached (step 314) and the process 300 ends.

If the retransmission counter does not exceed the maximum preamble retransmission limit, the WTRU checks whether any new RACH control parameters have been received, and if so, the RACH control parameters are updated with the most recent set of RACH control parameters (step 316). ).

The WTRU then performs a persistence check and determines whether the WTRU is allowed to transmit the preamble based on the persistence check (step 318). Based on this persistence value P _i , the WTRU determines whether to begin the preamble transmission procedure in the current random access interval. The duration of the random access interval is a design parameter and may be a single TTI, multiple TTIs, or part of a TTI. If transmission of the preamble is not allowed based on this persistence check, the WTRU waits for the next random access interval to perform another persistence check in the next random access interval (step 320). The persistence check is repeated until the transmission is allowed. If transmission of the preamble is allowed based on this persistence check, a random access procedure is initiated (steps 322-328).

The WTRU randomly selects a RACH subchannel among the plurality of available RACH subchannels in the selected ASC (step 322). The WTRU randomly selects a signature from the set of available signatures in the selected ASC (step 324). The random function for selecting the RACH subchannel and signature must ensure that each of the allowed selections is selected with equal probability.

The transmit power level for the preamble is set to a predetermined transmit power value for the preamble (step 326). Alternatively, the transmit power level for the preamble may be calculated using the open loop power control and interference information sent on the broadcast channel (BCH) from the cell (optional). The predetermined value may be set large enough to ensure that the signal-to-noise ratio (SNR) at the base station meets a predefined threshold in order for the base station to successfully decode the preamble. Due to the SC-FDMA structure, the large transmit power of the preamble is limited to the subcarrier (s), (or subcarrier block (s)) used only by the RACH, and does not affect other subcarriers or subcarrier blocks in the same cell. Do not. In conventional WCDMA systems, the initial transmit power of the preamble is set to a very low level and ramped up each time the preamble is retransmitted. This causes a significant delay until the preamble is detected by the base station. In contrast, according to the present invention, since the preamble is transmitted at a fairly high transmit power level, the RACH subchannel and signature are randomly selected, so that the delay is eliminated or reduced.

The WTRU then transmits the preamble at a predetermined or calculated power level using the selected signature over the selected RACH subchannel (step 328). After transmitting the preamble, the WTRU monitors the AICH to detect the AI sent by the base station in response to the preamble (step 330). AICH is a fixed rate physical channel used to convey AIs. The AICH may be spread over several subcarriers to have frequency diversity and make it more reliable. The AICH may be multiplexed on the downlink shared control channel. The AI corresponds to the signature on the RACH. There is a unique and fixed one-to-one mapping relationship of time and frequency location between RACH and AICH. Using the signature and a fixed one-to-one mapping relationship, the WTRU determines which AI is in response to its random access.

If no AI is detected on the AICH, the WTRU waits until the next uplink RACH subchannels are available in the time domain (step 332), and the process 300 returns to step 310 to retransmit the preamble. During retransmission of the preamble, the preamble transmit power level may or may not be ramped up.

In step 330, if it is determined that NACK is detected on the AICH, the WTRU waits until the next random access interval (step 334). The WTRU then sets a backoff timer and waits for this backoff timer to expire (step 336). The backoff timer, which is randomly selected between the minimum backoff period and the maximum backoff period, is preferably set to an integer multiple of 10 ms. The minimum backoff period and the maximum backoff period may be set equally when a fixed delay is required. The minimum backoff period and the maximum backoff period may be set to zero if no delay other than 1 is required due to duration. After expiration of the backoff timer, process 300 returns to step 310 to retransmit the preamble. During retransmission of the preamble, the preamble transmit power level may or may not be ramped up.

In step 330, if it is determined that an ACK is detected on the AICH, the WTRU sends a message portion to the base station (step 338). The message portion contains information that the user wants to send to the base station. The information in the message portion includes, but is not limited to, at least one of the following.

1) scheduling information, such as WTRU identification, data (traffic) type, data size, quality of service (QoS) information, and WTRU transmit power;

2) small amount of traffic data (optional);

3) layer 3 control messages;

4) uplink pilot signal; And

5) The transmission format indicator (TFI) of the message sent.

Upon transmission of the message portion, the WTRU may adjust the transmit power and timing and frequency of the message portion in accordance with each of the power adjustments and timing and frequency corrections generated by the base station, which will be described later with reference to FIG. will be. The message portion is sent to the N uplink access slots after the uplink access slots of the recently transmitted preambles according to the AICH transmission timing parameter. The transmit power in the control portion of the message portion should be P _pm dB higher than the transmit power of the last transmitted preamble. Both N and P _pm are design parameters.

4 is a flow diagram of a process 400 for processing a preamble at a base station in accordance with the present invention. The base station monitors the RACH subchannels to detect the preamble (step 402). The base station determines whether there is preamble transmission from other WTRUs on the same RACH subchannel (step 404).

If there is no preamble transmission from other WTRUs on the RACH subchannel used by this WTRU, then the SNR received at the base station is likely high enough to allow the base station to successfully decode the preamble. After successfully decoding the preamble, the base station sends an ACK back to the WTRU with the signature of the WTRU (step 406). Bit-by-bit multiplication of the signature and the ACK can be performed as in conventional WCDMA systems.

Optionally, the base station can calculate timing and frequency corrections and send them to the WTRU (step 408). Optionally, power adjustments may also be calculated and signaled to the WTRU. The base station calculates the difference between the SNR threshold required for successful decoding and the received SNR to calculate the power adjustment for the WTRU (ie, reduce transmit power for transmission of subsequent message portions of the WTRU). The power adjustment P _adjust is preferably calculated as follows.

[Equation 1]

P _adjust = max (SNR _received -SNR _required - Margin , 0);

Where Margin is a design parameter. All parameters in Equation (1) are in dB. The power adjustment may be implicitly conveyed in the resource allocation information in response to Node B's response to the preamble.

Since SC-FDMA is more sensitive to timing and frequency synchronization error than conventional WCDMA systems, the base station can process the preamble to derive the timing and frequency corrections for the WTRU, and send them along with the AI to the WTRU.

In step 404, if it is determined that there is at least one preamble transmitted by other WTRUs on the same RACH subchannel, it is further determined whether there is a preamble transmitted using the same signature (step 410). If there is at least one preamble transmitted using the same signature, a collision occurs and the base station sends a NACK to the WTRUs involved in the collision (ie, sends a NACK for this signature) (step 412). The base station may send a NACK with a signature. For example, bit-by-bit multiplication of the signature and the NACK may be performed as in a conventional WCDMA system.

In step 410, if it is determined that there is no preamble transmitted using the same signature, the received SNR is required for successful decoding, due to interference due to near far problem or cross correlation between signatures. The SNR may or may not be met. The base station generates an ACK for the WTRU that meets the received SNR that meets the required SNR (ie, an ACK for the signature used by the WTRU), and an ACK or None of the NACKs are generated (step 414). The base station may calculate power adjustments and timing and frequency corrections for the WTRUs where the received SNRs meet the required SNRs.

5 is a block diagram of a WTRU 500 implementing the process of FIG. The WTRU 500 includes a RACH processor 502 and a transmitter 504. The RACH processor 502 is configured to randomly select a RACH subchannel among the plurality of available RACH subchannels and randomly select a signature among the plurality of available signatures. The transmitter 504 is configured to transmit the preamble using the selected signature on the selected RACH subchannel at a predetermined or calculated transmit power level. The WTRU 500 may include a retransmission counter 506. This retransmission counter 506 is for tracking the number of retransmissions of the preamble. This retransmission counter 506 is initialized upon transmission of a new preamble and incremented each time the preamble is retransmitted. The transmitter 504 transmits the preamble only if the retransmission counter 506 does not exceed the retransmission limit.

6 is a block diagram of a base station 600 implementing the process of FIG. Base station 600 includes a preamble detector 602 and an AICH processor 604. Preamble detector 602 is configured to detect, on the RACH, the preamble sent by the WTRU. The AICH processor 604 is configured to send an AI to the WTRU when the preamble is detected on the RACH. Base station 600 may also include transmit power controller 606 and / or timing and frequency controller 608. The preamble detector 602 determines whether there is a preamble transmitted by another WTRU on the selected RACH subchannel, and the AICH processor 604 sends an ACK if there is no preamble transmitted by another WTRU on the selected RACH subchannel. Send it.

The transmit power controller 606 is configured to calculate a power adjustment based on the received power level of the preamble. The AICH processor 604 sends the power adjustment to the WTRU along with the AI to adjust the transmit power level of the message portion. Timing and frequency controller 608 is configured to calculate timing and frequency corrections based on this preamble. The AICH processor 604 sends timing and frequency corrections to the WTRU along with the AI to adjust timing and frequency.

Examples

1. A method for accessing a contention based uplink RACH in an SC-FDMA wireless communication system comprising a WTRU and a base station.

2. The method of embodiment 1 including the WTRU randomly selecting a RACH subchannel among the plurality of available RACH subchannels.

3. The method of embodiment 2 comprising the WTRU randomly selecting a signature from among a plurality of available signatures.

4. The method of embodiment 3 including transmitting a preamble using the selected signature on the selected RACH subchannel at a transmit power level sufficient for the WTRU to ensure successful decoding of the preamble by the base station.

5. The WTRU further includes selecting one ASC among the plurality of available ASCs, wherein available signatures and available RACH subchannels are provided per ASC, whereby the WTRU selects a RACH subchannel and signature based on the selected ASC. The method of any one of Examples 2 to 4.

6. The WTRU initializes the retransmission counter upon initial transmission of the preamble, increments the retransmission counter by 1 each time the WTRU retransmits the preamble, and transmits the preamble only if the retransmission counter does not exceed the retransmission limit. The method of Example 4 or 5.

7. The method of any of embodiments 4-6, further comprising the WTRU performing a persistence check prior to transmission of the preamble, wherein the WTRU transmits the preamble only if transmission of the preamble is allowed based on this persistence check. Way.

8. The method of embodiment 7 wherein the WTRU further comprises waiting for the next random access interval if transmission of the preamble is not allowed based on this persistence check.

9. The method of any of embodiments 4-8, further comprising the base station monitoring the RACH subchannel to detect the preamble.

10. The method of embodiment 9 further comprising the base station sending an AI to the WTRU when a signature is detected on the RACH, wherein the AI is one of ACK and NACK.

11. The method of any one of embodiments 9 and 10, wherein the WTRU includes monitoring the AICH to detect the AI.

12. The method of embodiment 11 if the ACK is detected, the WTRU sending a message portion to the base station.

13. The method of any one of embodiments 10-12 wherein the AICH is multiplexed on the downlink shared control channel.

14. The method of any of embodiments 10-13, wherein the base station determines whether there is a preamble transmitted by another WTRU on the selected subchannel.

15. The method of embodiment 14 wherein the base station sends an ACK if there is no preamble transmitted by another WTRU on the selected RACH subchannel.

16. The method of any one of embodiments 9-15, wherein the base station calculates a power adjustment based on the received power level of the preamble.

17. The method of embodiment 16, wherein the base station sends a power adjustment with the AI to the WTRU, wherein the WTRU adjusts the transmit power level of the message portion based on the power adjustment.

18. The method of any one of embodiments 9-17, wherein the base station calculates timing and frequency corrections based on the preamble.

19. The method of embodiment 18, wherein the base station sends timing and frequency corrections with the AI to the WTRU, wherein the WTRUs adjust the timing and frequency based on the timing and frequency corrections.

20. If there is at least one preamble transmitted by another WTRU on the selected RACH subchannel, the base station determining whether the signature used in the preamble transmitted by the other WTRU is the same as the selected signature. The method of any one of Examples 9-19 which is phosphorus.

21. The method of embodiment 20 if there is at least one preamble transmitted by another WTRU on the selected RACH subchannel, then the base station sends a NACK to the WTRU.

22. If the signature used by the other WTRU is different from the selected signature, then the base station sends an ACK to the WTRU that meets the required SNR and sends nothing to the WTRU that does not meet the required SNR. The method of any one of Examples 14-21.

23. The method of embodiment 22 further comprising the base station calculating a power adjustment based on the received power level of the preamble of the WTRU that meets the required SNR.

24. The method of embodiment 23, further comprising the base station sending a power adjustment to the WTRU, whereby the WTRU adjusts the transmit power level of the message portion based on the power adjustment.

25. The method of any one of embodiments 16-24, wherein power adjustments are implicitly conveyed in resource allocation information in response to the preamble.

26. The method of any one of embodiments 22-25, wherein the base station further comprises calculating timing and frequency corrections based on the preambles of the WTRUs that meet the required SNR.

27. The method of embodiment 26, wherein the base station sends timing and frequency corrections with the AI to the WTRU, whereby the WTRU adjusts timing and frequency based on the timing and frequency corrections.

28. The method of any one of embodiments 11-27, wherein if the AI is not detected, the WTRU further comprises waiting until the next available random access interval to retransmit the preamble.

29. The method of embodiment 11, further comprising, if the NACK is detected, the WTRU setting a backoff timer to retransmit the preamble upon expiration of the backoff timer, wherein the transmit power for retransmission of the preamble is not increased. To any one of 28 to 28.

30. The method of embodiment 29 wherein the backoff timer randomly selected between the minimum backoff period and the maximum backoff period is set to an integer multiple of 10 ms.

31. The method of embodiment 30 wherein the minimum backoff period and the maximum backoff period are set equal.

32. The method of embodiment 30 wherein the minimum backoff period and the maximum backoff period are set to zero.

33. The method of any one of embodiments 1-32, wherein the RACH subchannels are defined by at least one subcarrier over at least one time slot.

34. The method of any one of embodiments 1-32, wherein the RACH subchannels are defined by at least one subcarrier block comprising a plurality of subcarriers over at least one time slot.

35. The method of embodiment 34 wherein the subcarrier block is one of a distributed subcarrier block and a centralized subcarrier block.

36. The method of any one of embodiments 1-32, wherein the RACH subchannels are defined by at least one subcarrier over at least one time slot with at least one spreading code.

37. The method according to any one of embodiments 4 to 36, wherein the transmit power level of the preamble is predetermined.

38. The method of any one of embodiments 4-36, wherein the transmit power level of the preamble is calculated by the WTRU.

39. A WTRU for accessing a contention based uplink RACH in an SC-FDMA wireless communication system including a WTRU and a base station.

40. The WTRU of embodiment 39 comprising a RACH processor configured to randomly select a RACH subchannel among the plurality of available RACH subchannels and to randomly select a signature among the plurality of available signatures.

41. The WTRU of embodiment 40 comprising a transmitter configured to transmit the preamble using the selected signature on the selected RACH subchannel at a transmit power level sufficient to ensure successful decoding of the preamble by the base station.

42. The RACH processor is configured to select one ASC among a plurality of available ASCs, available signatures and available RACH subchannels are provided per ASC, and the RACH processor selects a RACH subchannel and signature based on the selected ASC. The WTRU of any one of Examples 40 and 41, which is phosphorus.

43. The WTRU of any one of embodiments 40-42, comprising a retransmission counter for tracking the number of retransmissions of the preamble, such that the transmitter transmits the preamble only if the retransmission counter does not exceed the retransmission limit.

44. The method of any one of embodiments 40-43, wherein the RACH processor is configured to perform a persistence check prior to transmission of the preamble, such that the transmitter transmits the preamble only if transmission of the preamble is allowed based on this persistence check. WTRU.

45. The WTRU of embodiment 44 wherein the RACH processor waits for the next random access interval if transmission of the preamble is not allowed based on this persistence check.

46. The WTRU of any one of embodiments 40-45, wherein the RACH processor monitors the AICH to detect the AI and sends a message portion to the base station when an ACK is detected.

47. The WTRU of embodiment 46 wherein the AICH is multiplexed on the downlink shared control channel.

48. The WTRU of any one of embodiments 46 and 47, wherein if the AI is not detected, the RACH processor waits until the next available RACH to retransmit the preamble.

49. If the NACK is detected, the RACH processor sets a backoff timer to retransmit the preamble upon expiration of the backoff timer, and the transmit power for retransmission of the preamble is not increased. The WTRU of any one of Examples 46-48.

50. The WTRU of embodiment 49 wherein the backoff timer randomly selected between the minimum backoff period and the maximum backoff period is set to an integer multiple of 10 ms.

51. The WTRU of embodiment 50, wherein the minimum backoff period and the maximum backoff period are set equal.

52. The WTRU of Embodiment 50, wherein the minimum backoff period and the maximum backoff period are set to zero.

53. The WTRU of any one of embodiments 39-52, wherein RACH subchannels are defined by at least one subcarrier over at least one time slot.

54. The WTRU of any one of embodiments 39-52, wherein RACH subchannels are defined by at least one subcarrier block that includes a plurality of subcarriers over at least one time slot.

55. The WTRU of embodiment 54 wherein the subcarrier block is one of a distributed subcarrier block and a centralized subcarrier block.

56. The WTRU of any one of embodiments 39-52, wherein RACH subchannels are defined by at least one subcarrier over at least one time slot with at least one spreading code.

57. The WTRU of any one of embodiments 41-56, wherein the transmit power level of the preamble is predetermined.

58. The WTRU of any one of embodiments 41-56, wherein the transmit power level of the preamble is calculated by the WTRU.

59. A base station for processing contention-based uplink RACH transmissions in an SC-FDMA wireless communication system including a WTRU and a base station.

60. The base station of embodiment 59 comprising a preamble detector configured to detect a preamble sent by the WTRU on the RACH.

61. The base station of embodiment 60, comprising an AICH processor configured to send an AI on the AICH when the preamble is detected on the RACH, wherein the AI is one of ACK or NACK.

62. The preamble detector determines whether there is a preamble transmitted by another WTRU on the selected RACH subchannel, and if there is no preamble transmitted by another WTRU on the selected RACH subchannel, the AICH processor sends an ACK. The base station of any one of embodiments 60 and 61.

63. A transmit power controller configured to calculate a power adjustment based on the received power level of the preamble, wherein the AICH processor sends the power adjustment to the WTRU, and the WTRU adjusts the transmit power level of the message portion based on this power adjustment. Base station in any one of embodiments 60-62.

64. The base station of embodiment 63 wherein the power adjustment is implicitly conveyed in resource allocation information in response to the preamble.

65. A timing and frequency controller configured to calculate timing and frequency corrections based on the preamble, wherein the AICH processor sends timing and frequency corrections to the WTRU along with the AI, and the WTRU is timing based on the timing and frequency corrections. And the base station of any one of embodiments 60-64.

66. If there is no at least one preamble sent by another WTRU on the selected RACH subchannel, the preamble detector is configured to determine whether the signature used in the preamble sent by the other WTRU is equal to the selected signature, and if so, the AICH. The base station of any one of embodiments 60-65 wherein the processor sends a NACK to the WTRU.

67. If the signature used by the other WTRUs is different from the selected signature, then the AICH processor sends an ACK to the WTRU that meets the required SNR and sends nothing to the WTRU that does not meet the required SNR. Base station.

68. A transmit power controller configured to calculate a power adjustment based on the received power level of the WTRU's preamble that meets the required SNR, wherein the AICH processor sends the power adjustment to the WTRU along with the AI, and the WTRU sends the power adjustment. The base station of embodiment 67, wherein the transmit power level of the message portion is adjusted based on the stationary.

69. A timing and frequency controller configured to calculate timing and frequency corrections based on the preambles of the WTRUs that meet the required SNR, wherein the AICH processor sends timing and frequency corrections to the WTRU along with the AI, and the WTRU The base station of any one of embodiments 67 and 68, wherein the timing and frequency are adjusted based on the timing and frequency correction values.

70. The base station of any one of embodiments 61-69, wherein the AICH is multiplexed on the downlink shared control channel.

While features and elements of the invention have been described in the preferred embodiments in particular combinations, each feature or element may be used alone without the other features and elements of the preferred embodiments, or other features and elements of the invention may be It may or may not be used in various combinations.

Claims (15)

In a wireless transmit receive unit (WTRU),
A processor configured to perform a cell search and recover control information from a channel of a selected cell in response to the performed cell search
Including,
The processor is further configured to transmit a random access preamble as a single carrier frequency division multiple access (SC-FDMA) signal based on the recovered control information;
The processor is further configured to receive a response to the random access preamble and recover timing advance, power command, and resource allocation from the response;
The processor also transmits a random access message as an SC-FDMA signal that uses at least resources derived from the resource allocation with at least a timing derived from the timing advance and at least a transmit power level derived from the power command. And a wireless transmit / receive unit (WTRU). The method of claim 1,
The resource allocation is indicative of a resource block for transmitting the random access message. The method of claim 2,
The resource block is indicative of subcarriers transmitting the random access message. The method of claim 3,
And wherein the indicated subcarriers are consecutive subcarriers. The method of claim 1,
Wherein the random access preamble is derived from at least a selected sequence and the received response indicates a selected sequence within the random access preamble. The method of claim 1,
And an SC-FDMA signal comprising the access message comprises pilot signals. The method of claim 1,
The duration of the random access preamble is one of a set of potential durations. The method of claim 1,
The transmit power level of the random access preamble is derived by open loop power control,
And the processor is further configured to transmit a subsequent preamble at an increased power level if a response to the random access preamble is not received. Performing a cell search and recovering control information from the channel of the selected cell in response to the performed cell search;
Based on the recovered control information, transmitting a random access preamble as a single carrier frequency division multiple access (SC-FDMA) signal;
Receiving a response to the random access preamble and recovering timing advance, power command, and resource allocation from the response; And
Transmitting a random access message as an SC-FDMA signal having at least timing derived from said timing advance and at least transmit power level derived from said power command and utilizing at least resources derived from said resource allocation;
How to include. 10. The method of claim 9,
And wherein the resource allocation indicates a resource block that transmits the random access message. The method of claim 10,
The resource block indicating subcarriers transmitting the random access message. The method of claim 11,
And the indicated subcarriers are consecutive subcarriers. 10. The method of claim 9,
Wherein the random access preamble is derived from at least a selected sequence and the received response indicates a selected sequence within the random access preamble. 10. The method of claim 9,
And the SC-FDMA signal including the random access message comprises pilot signals. 10. The method of claim 9,
The duration of the random access preamble is one of a set of potential durations.

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